Overturning circulation, nutrient limitation, and warming in the Glacial North Pacific

Although the Pacific Ocean is a major reservoir of heat and CO₂, and thus an important component of the global climate system, its circulation under different climatic conditions is poorly understood. Here, we present evidence that during the Last Glacial Maximum (LGM), the North Pacific was better ventilated at intermediate depths and had surface waters with lower nutrients, higher salinity, and warmer temperatures compared to today. Modeling shows that this pattern is well explained by enhanced Pacific meridional overturning circulation (PMOC), which brings warm, salty, and nutrient-poor subtropical waters to high latitudes. Enhanced PMOC at the LGM would have lowered atmospheric CO₂-in part through synergy with the Southern Ocean-and supported an equable regional climate, which may have aided human habitability in Beringia, and migration from Asia to North America.

Solution conformation of alpha-conotoxin EI, a neuromuscular toxin specific for the alpha 1/delta subunit interface of torpedo nicotinic acetylcholine receptor

A high resolution structure of alpha-conotoxin EI has been determined by (1)H NMR spectroscopy and molecular modeling. alpha-Conotoxin EI has the same disulfide framework as alpha 4/7 conotoxins targeting neuronal nicotinic acetylcholine receptors but antagonizes the neuromuscular receptor as do the alpha 3/5 and alpha A conotoxins. The unique binding preference of alpha-conotoxin EI to the alpha(1)/delta subunit interface of Torpedo neuromuscular receptor makes it a valuable structural template for superposition of various alpha-conotoxins possessing distinct receptor subtype specificities. Structural comparison of alpha-conotoxin EI with the gamma-subunit favoring alpha-conotoxin GI suggests that the Torpedo delta-subunit preference of the former originates from its second loop. Superposition of three-dimensional structures of seven alpha-conotoxins reveals that the estimated size of the toxin-binding pocket in nicotinic acetylcholine receptor is approximately 20 A (height) x 20 A (width) x 15 A (thickness).

A novel D-leucine-containing Conus peptide: diverse conformational dynamics in the contryphan family

A Conus peptide family (the contryphans) is noteworthy because of the presence of a post-translationally modified D-amino acid in all members of the family. A new contryphan peptide, Leu-contryphan-P, was isolated from the venom of Conus purpurascens; the sequence of this peptide is: Gly-Cys-Val-D-Leu-Leu-Pro-Trp-Cys-OH. This is the first known occurrence of D-leucine in a Conus peptide. The discovery of Leu-contryphan-P suggests that there may be branches of the contryphan peptide family that diverge much more in sequence than previously anticipated. Several natural contryphans provide dramatic examples of interconversion between multiple conformational states in small constrained peptides. The contryphans that have 4-trans-hydroxyproline and D-tryptophan in positions 3 and 4, respectively, exhibit two peaks under reverse-phase HPLC conditions, indicating interconversion between two discrete conformations. However, [L-Trp4]contryphan-Sm (with L-Trp substituted for D-Trp) exhibits a single, broad peak that elutes later than the natural peptide, suggesting that D-Trp stabilizes a conformation in which hydrophobic residues are buried. Leucontryphan-P which has valine and D-leucine instead of 4-trans-hydroxyproline and D-tryptophan shows only a single peak that elutes much later than the other contryphans.

An O-glycosylated neuroexcitatory conus peptide

We purified and characterized a novel peptide from the venom of the fish-hunting cone snail Conus striatus that inhibits voltage-gated K+ channels. The peptide, kappaA-conotoxin SIVA, causes characteristic spastic paralytic symptoms when injected into fish, and in frog nerve-muscle preparations exposed to the toxin, repetitive action potentials are seen in response to a single stimulus applied to the motor nerve. Other electrophysiological tests on diverse preparations provide evidence that is consistent with the peptide blocking K+ channels. The peptide has three disulfide bonds; the locations of Cys residues indicate that the spastic peptide may be the first and defining member of a new family of Conus peptides, the kappaA-conotoxins, which are structurally related to, but pharmacologically distinct from, the alphaA-conotoxins. This 30 AA tricyclic toxin has several characteristics not previously observed in Conus peptides. In addition to the distinctive biological and physiological activity, a novel biochemical feature is the unusually long linear N-terminal tail (11 residues) which contains one O-glycosylated serine at position 7. This is the first evidence for O-glycosylation as a posttranslational modification in a biologically active Conus peptide.

mu-Conotoxin PIIIA, a new peptide for discriminating among tetrodotoxin-sensitive Na channel subtypes

We report the characterization of a new sodium channel blocker, mu-conotoxin PIIIA(mu-PIIIA). The peptide has been synthesized chemically and its disulfide bridging pattern determined. The structure of the new peptide is: [sequence: see text] where Z = pyroglutamate and O = 4-trans-hydroxyproline. We demonstrate that Arginine-14 (Arg14) is a key residue; substitution by alanine significantly decreases affinity and results in a toxin unable to block channel conductance completely. Thus, like all toxins that block at Site I, mu-PIIIA has a critical guanidinium group. This peptide is of exceptional interest because, unlike the previously characterized mu-conotoxin GIIIA (mu-GIIIA), it irreversibly blocks amphibian muscle Na channels, providing a useful tool for synaptic electrophysiology. Furthermore, the discovery of mu-PIIIA permits the resolution of tetrodotoxin-sensitive sodium channels into three categories: (1) sensitive to mu-PIIIA and mu-conotoxin GIIIA, (2) sensitive to mu-PIIIA but not to mu-GIIIA, and (3) resistant to mu-PIIIA and mu-GIIIA (examples in each category are skeletal muscle, rat brain Type II, and many mammalian CNS subtypes, respectively). Thus, mu-conotoxin PIIIA provides a key for further discriminating pharmacologically among different sodium channel subtypes.

kappa-Conotoxin PVIIA is a peptide inhibiting the shaker K+ channel

kappa-Conotoxin PVIIA (kappa-PVIIA), a 27-amino acid toxin from Conus purpurascens venom that inhibits the Shaker potassium channel, was chemically synthesized in a biologically active form. The disulfide connectivity of the peptide was determined. kappa-Conotoxin PVIIA has the following structure. This is the first Conus peptide known to target K+ channels. [structure: see text] Although the Shaker K+ channel is sensitive to kappa-PVIIA, the rat brain Kv1.1 subtype is resistant. Chimeras between Shaker and the Kv1.1 K+ channels were constructed and expressed in Xenopus oocytes. Only channels containing the putative pore-forming region between the fifth and sixth transmembrane domains of Shaker retained toxin sensitivity, indicating that the toxin target site is in this region of the channel. Evidence is presented that kappa-PVIIA interacts with the external tetraethyl-ammonium binding site on the Shaker channel. Although both kappa-PVIIA and charybdotoxin inhibit the Shaker channel, they must interact differently. The F425G Shaker mutation increases charybdotoxin affinity by 3 orders of magnitude but abolishes kappa-PVIIA sensitivity. The precursor sequence of kappa-PVIIA was deduced from a cDNA clone, revealing a prepropeptide comprising 72 amino acids. The N-terminal region of the kappa-PVIIA prepropeptide exhibits striking homology to the omega-, muO-, and delta-conotoxins. Thus, at least four pharmacologically distinct superfamilies of Conus peptides belong to the same "O" superfamily, with the omega- and kappa-conotoxins forming one branch, and the delta- and muO-conotoxins forming a second major branch.

Differential targeting of nicotinic acetylcholine receptors by novel alphaA-conotoxins

We describe the isolation and characterization of two peptide toxins from Conus ermineus venom targeted to nicotinic acetylcholine receptors (nAChRs). The peptide structures have been confirmed by mass spectrometry and chemical synthesis. In contrast to the 12-18 residue, 4 Cys-containing alpha-conotoxins, the new toxins have 30 residues and 6 Cys residues. The toxins, named alphaA-conotoxins EIVA and EIVB, block both Torpedo and mouse alpha1-containing muscle subtype nAChRs expressed in Xenopus oocytes at low nanomolar concentrations. In contrast to alpha-bungarotoxin, alphaA-EIVA is inactive at alpha7-containing nAChRs even at micromolar concentrations. In this regard, alphaA-EIVA is similar to the previously described alpha-conotoxins (e.g. alpha-MI and alpha-GI) which also selectively target alpha1- versus alpha7-containing nAChRs. However, alpha-MI and alpha-GI discriminate between the alpha/delta versus alpha/gamma subunit interfaces of the mouse muscle nAChR with 10,000-fold selectivity. In contrast, alphaA-conotoxin EIVA blocks both the alpha/gamma site and alpha/delta site with equally high affinity but with distinct kinetics. The alphaA-conotoxins thus represent novel probes for the alpha/gamma as well as the alpha/delta binding sites of the nAChR.

A noncompetitive peptide inhibitor of the nicotinic acetylcholine receptor from Conus purpurascens venom

A paralytic peptide, psi-conotoxin Piiie has been purified and characterized from Conus purpurascens venom. Electrophysiological studies indicate that the peptide inhibits the nicotinic acetylcholine receptor (nAChR). However, the peptide does not block the binding of alpha-bungarotoxin, a competitive nAChR antagonist. Thus, psi-conotoxin Piiie appears to inhibit the receptor at a site other than the acetylcholine-binding site. As ascertained by sequence analysis, mass spectrometry, and chemical synthesis, the peptide has the following covalent structure: HOOCCLYGKCRRYOGCSSASCCQR* (O = 4-trans hydroxyproline; * indicates an amidated C-terminus). The disulfide connectivity of the toxin is unrelated to the alpha- or the alphaA-conotoxins, the Conus peptide families that are competitive inhibitors of the nAChR, but shows homology to the mu-conotoxins (which are Na+ channel blockers).

Determinants involved in the affinity of alpha-conotoxins GI and SI for the muscle subtype of nicotinic acetylcholine receptors

Nicotinic acetylcholine receptors from muscle contain two functionally active and pharmacologically distinct acetylcholine-binding sites located at the alpha/gamma and alpha/delta subunit interfaces. The alpha-conotoxins are competitive antagonists of nicotinic receptors and can be highly site-selective, displaying greater than 10,000-fold differences in affinities for the two acetylcholine-binding sites on a single nicotinic receptor. The higher affinity site for alpha-conotoxins GI, MI, and SI is the alpha/delta site on mouse muscle-derived BC3H-1 receptors. However, alpha-conotoxins GI and MI exhibit higher affinity for the other site (alpha/gamma site) on nicotinic receptors from Torpedo californica electric organ. alpha-Conotoxin SI does not distinguish between the two acetylcholine-binding sites on Torpedo receptors. In this study, alpha-conotoxins [K10H]SI and [K10N]SI displayed wild-type affinity for the two acetylcholine-binding sites on BC3H-1 receptors but a 10-20-fold decrease in apparent affinity at one of the two acetylcholine-binding sites on Torpedo receptors. alpha-Conotoxin [P9K]SI displayed a selective and dramatic increase in the apparent affinity for the alpha/delta site of BC3H-1 receptors and for the alpha/gamma site of Torpedo receptors. alpha-Conotoxin [R9A]GI displayed a reduction in affinity for both acetylcholine-binding sites on BC3H-1 receptors, although the extent of its selectivity for the alpha/delta site was retained. alpha-Conotoxin [R9A]GI also displayed a loss of affinity for the two acetylcholine-binding sites on Torpedo receptors, but its site-selectivity was apparently abolished. These results indicate that positions 9 and 10 in alpha-conotoxins GI and SI are involved in complex species- and subunit-dependent interactions with nicotinic receptors.

NMR structure determination of a novel conotoxin, [Pro 7,13] alpha A-conotoxin PIVA

A high-resolution solution conformation of a novel conotoxin, [Pro 7,13] alpha A-conotoxin PIVA, GCCGSYPNAACHPCSCKDROSYCGQ-NH2, has been determined by two-dimensional 1H NMR methods and distance geometry calculations. The total of 324 NOE-derived interproton distance restraints including 33 long-range NOE restraints as well as 11 phi and 7 chi 1 torsion angle restraints was used for computation of structures. Back-calculation from the experimental NOE spectrum has provided 49 new NOE restraints and yielded the final R-factors of Ra = 0.641 and Rb = 0.157. The final RMSD values are 0.90 and 1.16 A for the backbone and the heavy atoms, respectively. The C-terminal half of the molecule involving the residues 12-24 is extremely well-defined with a backbone RMSD value of 0.56 A, whereas the N-terminal 3-11 disulfide loop is relatively flexible, possessing a backbone RMSD value of 1.09 A. The [Pro 7,13] alpha A-conotoxin PIVA does not contain any significant secondary structure although the 21S-24G nearly completes one turn of a 3(10) helix. The overall protein fold is largely maintained by the three disulfide bridges of 2-16, 3-11, and 14-23. The presence of the three disulfide bridges imposes geometric constraints that force the molecule to form six continuous bends involving the following residues: 3C-5S, 7P-10A, 12H-14C, 15S-17K, 17K-19R, and 21S-25Q. The overall shape of the [Pro 7,13] alpha A-conotoxin PIVA can be described as an "iron". Residues 15S-19R form a loop that protrudes out of the "bottom plate" formed by the rest of the protein and constitute the handle of the iron. The N-terminal tip of the molecule is relatively immobile due to attractive electrostatic interactions between the gamma-hydroxyl group of 20 Hyp and the phenolic hydroxyl group of 22Y. The flexible 3-11 disulfide loop consists mostly of hydrophobic residues, while the best-defined 14-23 disulfide loop contains the highly charged hydrophilic 15S-19R "handle" domain exposed to the exterior of the protein. Binding to nicotinic acetylcholine receptor can be mediated through two different types of interactions: one involving the aromatic hydrophobic residues such as 6Y and 12H and the other involving the positively charged hydrophilic side chain of the 19R. The side chain of the 19R in the [Pro 7, 13] alpha A-conotoxin PIVA and that of the 9R of the alpha-conotoxin G1, and also the side chains of the 12H and 6Y in the former and those of 10H and 11Y in the latter can be aligned to point to the same direction when the corresponding backbone atoms are superimposed to an RMSD value of 2.5 A.

Bromocontryphan: post-translational bromination of tryptophan

We demonstrate that post-translational bromination of a tryptophan residue occurs in the biologically active octapeptide bromocontryphan, purified and characterized from Conus radiatus venom. Clones encoding bromocontryphan were identified from a cDNA library made from C. radiatus venom ducts. The mRNA sequence obtained predicts a prepropeptide which has the mature peptide sequence at the C-terminal end, with the L-6-bromotryptophan residue encoded by UGG, the Trp codon. These data provide the first direct evidence for post-translational bromination of a polypeptide which is translated through the normal cellular machinery. In addition to bromination, the peptide, which induces a "stiff tail" syndrome in mice, has several other modifications as shown by the sequence [Formula: See Text] in which Hyp = hydroxyproline. Asterisks indicate post-translational modifications (left to right): proteolytic cleavage at the N-terminus; hydroxylation of Pro3; epimerization of Trp4; bromination of Trp7, and C-terminal amidation. Bromocontryphan appears to have the highest density of post-translational modifications known among gene-encoded polypeptides. The overall result is a molecule which closely resembles marine natural products produced through specialized biosynthetic pathways comprising many enzyme-catalyzed steps.

Folding of omega-conotoxins. 1. Efficient disulfide-coupled folding of mature sequences in vitro

Disulfide-coupled refolding reactions of five omega-conotoxins, Ca2+ channel antagonists derived from marine snails of the genus Conus, were examined. These peptides are 23-26 amino acid residues long, and the native conformation of each is stabilized by three disulfide bonds. Although the primary structures of the peptides show only limited sequence similarity, the patterns of disulfides and three-dimensional conformations are very similar. Refolding of the reduced proteins was promoted by the disulfide form of glutathione (GSSG) in the presence of reduced glutathione (GSH). All five of the peptides examined were able to refold to the native conformation, as judged by reversed-phase HPLC behavior, with efficiencies of 16% for omega-MVIIC, 28% for omega-MVIID, and 50% for omega-MVIIA, omega-GVIA, and omega-SVIA. The refolded form of omega-MVIIA was further shown to have biological activity indistinguishable from that of the native form, as well as the same rate of reductive unfolding in the presence of dithiothreitol. The overall folding rate and efficiency of omega-MVIIA was found to be quite sensitive to the thiol-disulfide redox potential, with optimum rates and yields obtained in the presence of GSSG and GSH at concentrations similar to those believed to be present in the endoplasmic reticulum. The folding efficiency of this peptide was greatly reduced by the addition of 8 M urea, indicating that formation of the correct disulfides is determined largely by noncovalent interactions, as opposed to steric constraints arising from the spacing between Cys residues. These results demonstrate that the mature forms of at least some omega-conotoxins contain sufficient information to direct correct folding and disulfide formation, in spite of their small size and limited sequence conservation.

Folding of omega-conotoxins. 2. Influence of precursor sequences and protein disulfide isomerase

The peptide Ca2+ channel antagonists found in the venoms of Conus snails, omega-conotoxins, are synthesized as precursors that include a leader peptide, presumed to direct the polypeptide to the endoplasmic reticulum, and a propeptide of unknown function. In addition, the precursors are synthesized with a C-terminal Gly residue that is posttranslationally converted to a terminal amide group. In order to determine whether the precursor sequences contain information that helps direct folding of the mature sequences, the disulfide-coupled folding of mature omega-conotoxin MVIIA was compared with that of two putative precursor forms: pro-omega-MVIIA-Gly, which contains the propeptide and the C-terminal Gly residue, and omega-MVIIA-Gly, which differs from the mature form only at the C-terminus. The three forms folded with similar kinetics, but the folding efficiency of omega-MVIIA-Gly was greater than 80%, versus approximately 50% for both mature omega-MVIIA and the form containing the propeptide. The enzyme protein disulfide isomerase was found to catalyze disulfide formation and folding of all three forms similarly. The affinity of omega-MVIIA-Gly for receptors in chick brain synaptosomes was approximately 10-fold lower than that of the mature peptide, and the N-terminal propeptide of pro-omega-MVIIA-Gly was found to decrease binding further, by approximately 100-fold. These results suggest that the omega-conotoxins do not rely on the propeptide region of their precursors to facilitate folding. Rather, the mature sequence contains most of the information required to specify the native disulfide pairings and three-dimensional conformation. The C-terminal Gly may enhance the folding efficiency by forming interactions that stabilize the native conformation with respect to other disulfide-bonded forms.

Contryphan is a D-tryptophan-containing Conus peptide

In this report, we document for the first time the occurrence of D-tryptophan in a normally translated polypeptide, contryphan. The peptide, isolated from the venom of the fish-hunting marine snail Conus radiatus, produces the "stiff-tail" syndrome in mice. Characterization of the octapeptide gave the following sequence, Gly-Cys-Hyp-D-Trp-Glu-Pro-Trp-Cys-NH2 where Hyp = 4-trans-hydroxyproline. The presence of D-tryptophan in position 4 of contryphan was confirmed by chemical synthesis. The post-translational epimerization in all other D-amino acid-containing small peptides characterized previously from vertebrates and molluscan systems is in position 2.

Three-dimensional structure of the alpha-conotoxin GI at 1.2 A resolution

Predatory marine snails of the genus Conus paralyze their fish prey by injecting a potent toxin. The alpha-conotoxin GI is a 13-residue peptide isolated from venom of Conus geographus. It functions by blocking the postsynaptic nicotinic acetylcholine receptor. After crystallization in deionized water, the three-dimensional structure of the GI neurotoxin was determined to 1.2 A resolution by X-ray crystallography. This structure, which can be described as a triangular slab, shows overall similarities to those derived by NMR, CD, and predictive methods. The principal framework of the molecule is provided by two disulfide bonds, one linking Cys 2 and Cys 7 and the other Cys 3 and Cys 13. Opposite ends of the sequence are drawn together even further by hydrogen bonds between Glu 1 and Cys 13 and between Cys 2 and Ser 12. Since the C-terminus is amidated, only one negative charge is present (carboxylate of Glu 1), and this is not implicated in receptor binding. Two positively charged regions (the alpha-amino group of Glu 1 and the guanido group of Arg 9) are situated 15 A apart at the corners of the triangular face of the molecule. phi, psi angles characteristic of a 3(10) helix were observed for residues 5-7. For residues 8-11, these angles were consistent with either a type I beta-turn or a distorted 3(10) helix.

A new alpha-conotoxin which targets alpha3beta2 nicotinic acetylcholine receptors

We have isolated a 16-amino acid peptide from the venom of the marine snail Conus magus which potently blocks nicotinic acetylcholine receptors (nAChRs) composed of alpha3beta2 subunits. This peptide, named alpha-conotoxin MII, was identified by electrophysiologically screening venom fractions against cloned nicotinic receptors expressed in Xenopus oocytes. The peptide's structure, which has been confirmed by mass spectrometry and total chemical synthesis, differs significantly from those of all previously isolated alpha-conotoxins. Disulfide bridging, however, is conserved. The toxin blocks the response to acetylcholine in oocytes expressing alpha3beta2 nAChRs with an IC50 of 0.5 nM and is 2-4 orders of magnitude less potent on other nAChR subunit combinations. We have recently reported the isolation and characterization of alpha-conotoxin ImI, which selectively targets homomeric alpha7 neuronal nAChRs. Yet other alpha-conotoxins selectively block the muscle subtype of nAChR. Thus, it is increasingly apparent that alpha-conotoxins represent a significant resource for ligands with which to probe structure-function relationships of various nAChR subtypes.

alpha-Conotoxin EI, a new nicotinic acetylcholine receptor antagonist with novel selectivity

We report the isolation and characterization of a novel nicotinic acetylcholine receptor (nAChR) ligand. The toxin is an 18 amino acid peptide and is the first reported alpha-conotoxin from an Atlantic fish-hunting Conus. The peptide was purified from the venom of Conus ermineus and is called alpha-conotoxin EI. The sequence diverges from that of previously isolated alpha-conotoxins. We demonstrate that this structural divergence has functional consequences. In Torpedo nAChRs, alpha-conotoxin EI selectively binds the agonist site near the alpha/delta subunit interface in contrast to alpha-conotoxin MI which selectively targets the alpha/gamma agonist binding site. In mammalian nAChRs alpha-conotoxin EI shows high affinity for both the alpha/delta and alpha/gamma subunit interfaces (with some preference for the alpha/delta site), whereas alpha-conotoxin MI is highly selective for the alpha/delta ligand binding site. The sequence of the peptide is: Arg-Asp-Hyp-Cys-Cys-Tyr-His-Pro-Thr-Cys-Asn-Met-Ser-Asn-Pro-Gln-Ile-Cys- NH2, with disulfide bridging between Cys4-Cys10 and Cys5-Cys18, analogous to those of previously described alpha-conotoxins. This sequence has been verified by total chemical synthesis. Thus, alpha-conotoxin EI is a newly-available tool with unique structure and function for characterization of nAChRs.

A new family of Conus peptides targeted to the nicotinic acetylcholine receptor

In this work, a new family of Conus peptides, the alpha A-conotoxins, which target the nicotinic acetylcholine receptor, is defined. The first members of this family have been characterized from the eastern Pacific species, Conus purpurascens (the purple cone); three peptides that cause paralysis in fish were purified and characterized from milked venom. The sequence and disulfide bonding pattern of one of these, alpha A-conotoxin PIVA, is as follows: [formula: see text] where O represents trans-4-hydroxyproline. The two other peptides purified from C. purpurascens venom are the under-hydroxylated derivatives, [Pro13]alpha A-conotoxin PIVA and [Pro7,13]alpha A-conotoxin PIVA. The peptides have been chemically synthesized in a biologically active form. Both electrophysiological experiments and competition binding with alpha-bungarotoxin demonstrate that alpha A-PIVA acts as an antagonist of the nicotinic acetylcholine receptor at the postsynaptic membrane.

A new family of conotoxins that blocks voltage-gated sodium channels

Conus peptides, including omega-conotoxins and alpha-conotoxins (targeting calcium channels and nicotinic acetylcholine receptors, respectively) have been useful ligands in neuroscience. In this report, we describe a new family of sodium channel ligands, the mu-O-conotoxins. The two peptides characterized, mu-O-conotoxins MrVIA and MrVIB from Conus marmoreus potently block the sodium conductance in Aplysia neurons. This is in marked contrast to standard sodium channel blockers that are relatively ineffective in this system. The sequences of the peptides are as follows. mu-O-conotoxin MrVIA: ACRKKWEYCIVPIIGFIYCCPGLICGPFVCV mu-O-conotoxin MrVIB: ACSKKWEYCIVPILGFVYCCPGLICGPFVCV mu-O-conotoxin MrVIA was chemically synthesized and proved indistinguishable from the natural product. Surprisingly, the mu-O-conotoxins show no sequence similarity to the mu-O-conotoxins. However, ananalysis of cDNA clones encoding the mu-O-conotoxin MrVIB demonstrated striking sequence similarity to omega- and delta-conotoxin precursors. Together, the omega-, delta-, and mu-O-conotoxins define the O-superfamily of Conus peptides. The probable biological role and evolutionary affinities of these peptides are discussed.

Purification, characterization, synthesis, and cloning of the lockjaw peptide from Conus purpurascens venom

The major groups of Conus peptides previously characterized from fish-hunting cone snail venoms (the alpha-, mu-, and omega-conotoxins) all blocked neuromuscular transmission. A novel activity, the "lockjaw peptide", from the fish-hunting Conus purpurascens, caused a rigid (instead of flaccid) paralysis in fish and increased excitability at the neuromuscular junction (instead of a block). We report the purification, biological activity, biochemical and preliminary physiological characterization, and chemical synthesis of the lockjaw peptide and the sequence of a cDNA clone encoding its precursor. Taken together, the data lead us to conclude that the lockjaw peptide is a vertebrate-specific delta-conotoxin, which targets voltage-sensitive sodium channels. The sequence of the peptide, which we designate delta-conotoxin PVIA, is (O = 4-trans-hydroxyproline) EACYAOGTFCGIKOGLCCSEFCLPGVCFG-NH2. This is the first of a diverse spectrum of Conus peptides which are excitotoxins in vertebrate systems.

Rat corticostatin R4: synthesis, disulfide bridge assignment, and in vivo activity

We have synthesized significant amounts of the most potent member of the rat corticostatins that inhibits ACTH-induced corticosteroid and compared its structure to that of the natural hormone. The cystine bridging arrangement that corresponds to that reported for a human defensin (3-31, 5-20, 10-30) was determined. The in vitro corticostatic activity of the synthetic rat corticostatin R4 paralleled that of the natural R4. Biological studies in vivo showed that doses of 8 or 12 mg corticostatin/kg effectively interfered with corticosterone release in stressed rats. We conclude that in the assays that were used, the biological activity of the synthetic and natural molecules was identical. The availability of significant amounts of synthetic material will make possible studies investigating the physiological role played by corticostatins in modulating the activity of the hypothalamic-pituitary-adrenal axis.

Delta-conotoxin GmVIA, a novel peptide from the venom of Conus gloriamaris

A novel peptide toxin, delta-conotoxin GmVIA, was purified from the venom of Conus gloriamaris, a mollusc-hunting snail. It consists of 29 amino acids, including six Cys residues: [sequence: see text] The pattern of disulfide connectivity (4-19, 12-24, and 18-29) is the same as for the omega-conotoxins, which are Ca2+ channel ligands. However, the peptide does not compete with omega-conotoxin for binding to membrane preparations from frog, rat, and chick brain. Instead, initial electrophysiological results suggest that the peptide induces action potential broadening in molluscan neurons by slowing down Na+ current inactivation. Synthetic delta-conotoxin GmVIA was prepared by solid-phase methods and appeared identical in all respects to the natural material. The chromatographic behavior of native and reduced delta-conotoxins is quite remarkable, suggesting that the disulfides form a core which forces hydrophobic residues to point out toward the solvent.

The distribution of omega-conotoxin MVIICnle-binding sites in rat brain measured by autoradiography

An analogue of omega-conotoxin MVIIC, [125I]omega-MVIICnle, has been employed in an autoradiographic assay to define the distribution of binding sites in rat brain of this neuronal calcium channel antagonist. In comparison with N-type channels (labeled by [125I]omega conotoxin GVIA), omega-MVIICnle sites are much denser in cerebellum (molecular layer) than in forebrain. Binding in thalamus is also comparatively high for omega-MVIICnle. Under these conditions, [125I]omega-MVIICnle binding to rat brain sections is not displaceable by the N-channel antagonist, omega-conotoxin GVIA. The calcium channel blocker [125I]omega-conotoxin MVIICnle labels a unique set of binding sites in mammalian brain.

A nicotinic acetylcholine receptor ligand of unique specificity, alpha-conotoxin ImI

We report the isolation, characterization, and total synthesis of a small peptide ligand for nicotinic acetylcholine receptors (nAChRs). It is highly active against the neuromuscular receptor in frog but not in mice. In contrast, it induces seizures when injected centrally in mice and rats, suggesting that it may target neuronal nAChRs in mammals. Although such receptors may be important in both normal cognition and the pathophysiology of several neuropsychiatric disorders, there are few ligands to discriminate between the multiple receptor subtypes. The new peptide is a highly divergent alpha-conotoxin from the snail Conus imperialis, which preys on polychaete worms. In this article, the purification, structural analysis, synthesis, and preliminary physiological characterization of alpha-conotoxin ImI (alpha-CTx-ImI) are reported. The sequence of the peptide is: Gly-Cys-Cys-Ser-Asp-Pro-Arg-Cys-Ala-Trp-Arg-Cys-NH2. The peptide shows striking sequence differences from all alpha-conotoxins of fish-hunting Conus, but its disulfide-bridging is similar: [2-8; 3-12]. We suggest that cone venoms may provide an array of ligands with selectivity for various neuronal nAChR subtypes.

A new Conus peptide ligand for Ca channel subtypes

A cDNA clone encoding a new omega-conotoxin was identified from Conus magus. The predicted peptide was chemically synthesized using a novel strategy that efficiently yielded the biologically active disulfide-bonded isomer. This peptide, omega-conotoxin MVIID, targets other voltage-gated calcium channels besides the N-subtype and exhibits greater discrimination against the N-channel subtype than any other omega-conotoxin variant to date. Consequently, omega-conotoxin MVIID may be a particularly useful ligand for calcium channel subtypes that are not of the L- or N-subclasses. Of the eight major sequence variants of omega-conotoxins that have been elucidated, four come from Conus magus venom. We suggest that sequence variants from the same venom may be designed to optimally interact with different molecular variants of calcium channels; such omega-conotoxin sets from a single venom may therefore be useful for helping to identify novel calcium channel subtypes.

Echistatin disulfide bridges: selective reduction and linkage assignment

Echistatin is the smallest member of the disintegrin family of snake venom proteins, containing four disulfides in a peptide chain of 49 residues. Partial assignment of disulfides has been made previously by NMR and chemical approaches. A full assignment was made by a newly developed chemical approach, using partial reduction with tris-(2-carboxyethyl)-phosphine at acid pH. Reduction proceeded in a stepwise manner at pH 3, and the intermediates were isolated by high performance liquid chromatography. Alkylation of free thiols, followed by sequencer analysis, enabled all four bridges to be identified: (1) at 20 degrees C a single bridge linking Cys 2-Cys 11 was broken, giving a relatively stable intermediate; (2) with further treatment at 41 degrees C the bridges Cys 7-Cys 32 and Cys 8-Cys 37 became accessible to the reagent and were reduced at approx. equal rates; (3) the two bicyclic peptides produced in this manner were less stable and could be reduced at 20 degrees C to a peptide that retains a single bridge linking Cys 20-Cys 39; and (4) the monocyclic peptide can be reduced to the linear molecule at 20 degrees C. Some disulfide exchange occurred during alkylation of the bicyclic intermediates, but results unambiguously show the pattern to be [2-11; 7-32; 8-37; 20-39]. A comparison is made with kistrin, a longer disintegrin whose disulfide structure has been proposed from NMR analysis.

Disulfide structures of highly bridged peptides: a new strategy for analysis

A new approach is described for analyzing disulfide linkage patterns in peptides containing tightly clustered cystines. Such peptides are very difficult to analyze with traditional strategies, which require that the peptide chain be split between close or adjacent Cys residues. The water-soluble tris-(2-carboxyethyl)-phosphine (TCEP) reduced disulfides at pH 3, and partially reduced peptides were purified by high performance liquid chromatography with minimal thiol-disulfide exchange. Alkylation of free thiols, followed by sequencer analysis, provided explicit assignment of disulfides that had been reduced. Thiol-disulfide exchange occurred during alkylation of some peptides, but correct deductions were still possible. Alkylation competed best with exchange when peptide solution was added with rapid mixing to 2.2 M iodoacetamide. Variants were developed in which up to three alkylating agents were used to label different pairs of thiols, allowing a full assignment in one sequencer analysis. Model peptides used included insulin (three bridges, intra- and interchain disulfides; -Cys.Cys- pair), endothelin and apamin (two disulfides; -Cys.x.Cys- pair), conotoxin GI and isomers (two disulfides; -Cys.Cys- pair), and bacterial enterotoxin (three bridges within 13 residues; two -Cys.Cys- pairs). With insulin, all intermediates in the reduction pathway were identified; with conotoxin GI, analysis was carried out successfully for all three disulfide isomers. In addition to these known structures, the method has been applied successfully to the analysis of several previously unsolved structures of similar complexity. Rates of reduction of disulfide bonds varied widely, but most peptides did not show a strongly preferred route for reduction.

Three-dimensional structure of an Fv from a human IgM immunoglobulin

An IgM(kappa) immunoglobulin from a patient (Pot) with Waldenstrom's macroglobulinemia was hydrolyzed with pepsin to release a fragment consisting of the 'variable' (V) domains of the light and heavy chains plus eight residue 'tails' from the 'constant' (C) domains. The crystal structure of this fragment was determined at 2.3 A resolution by molecular replacement and crystallographic refinement methods. When examined separately, the light chain component closely resembles another human kappa chain (Rei) in both the beta-pleated sheet regions and the 'hypervariable' loops. The conserved pleated sheets in the heavy chain are similar to those in the human Kol IgG1 protein, but the third hypervariable loop in particular is different from that in any immunoglobulin structure described to date. As in the Kol protein, this loop blocks the access to any internal active site along the light-heavy chain interface. Unlike the Kol protein, however, the loop does not protrude beyond the boundaries of a conventional antigen combining site. Instead, it forms a very compact structure, which fills almost all residual space between the domains. This is an example of one dominant complementarity-determining region (CDR) essentially negating the diversity possible with five other CDRs in the two chains. Ordered water molecules are associated with light chain constituents along the interface, but not with CDR3 of the heavy chain. In screening exercises the Pot IgM failed to bind a wide variety of peptides. Together, the results suggest that ligand binding can only occur on external surfaces of the protein. These surfaces carry a limited number of side chains usually assigned to CDRs in more typical antibodies.

Novel alpha- and omega-conotoxins from Conus striatus venom

Three neurotoxic peptides from the venom of Conus striatus have been purified, biochemically characterized, and chemically synthesized. One of these, an acetylcholine receptor blocker designated alpha-conotoxin SII, has the sequence GCCCNPACGPNYGCGTSCS. In contrast to all other alpha-conotoxins, SII has three disulfide bonds (instead of two), has no net positive charge, and has a free C-terminus. The other two paralytic peptides are Ca channel-targeted omega-conotoxins, SVIA and SVIB. omega-SVIA is the smallest natural omega-conotoxin so far characterized and has the sequence CRSSGSPCGVTSICCGRCYRGKCT-NH2. Although omega-conotoxin SVIA is a potent paralytic toxic in lower vertebrate species, it was much less effective in mammals. The third toxin, omega-conotoxin SVIB, has the sequence CKLKGQSCRKTSYDCCSGSCGRSGKC-NH2. This peptide has a different pharmacological specificity from other omega-conotoxins previously purified from Conus venoms; only omega-conotoxin SVIB has proven to be lethal to mice upon ic injection. Binding competition experiments with rat brain synaptosomal membranes indicate that the high-affinity binding site for omega-conotoxin SVIB is distinct from the high-affinity omega-conotoxin GVIA or MVIIA site.

Conopressin G, a molluscan vasopressin-like peptide, alters gill behaviors in Aplysia

Superfusion of an invertebrate vasopressin structural analogue, conopressin G, over the abdominal ganglion of an in vitro preparation of Aplysia californica has significant neurophysiological and behavioral effects. Both the amplitude of the siphon-evoked gill withdrawal reflux and concomitant activity in gill motor neurons are reduced in the presence of conopressin G. Moreover, the frequency of spontaneous gill movements and their neural correlate, interneuron II activity, are increased. These behavioral modifications strongly resemble those that occur during the food-aroused behavioral state in intact Aplysia. In addition, conopressin G superfusion reduces both the excitability of gill motor neurons and the strength of gill contractions in response to gill motor neuron discharges elicited by direct depolarizing current. A role for conopressin G or a similar peptide in the modulation of gill behaviors associated with the food-aroused state is suggested.

alpha-Conotoxins, small peptide probes of nicotinic acetylcholine receptors

alpha-Conotoxins, a family of small peptides from the venoms of the Conus marine moluscs, are selective, snake alpha-neurotoxin-competitive antagonists of the nicotinic acetylcholine receptor. A new alpha-conotoxin, SIA, has been purified, sequenced, and synthesized. Cross-linking with bivalent reagents and photoaffinity labeling of the acetylcholine receptor with alpha-conotoxin yield covalent adducts. Surprisingly, cross-linking to other subunits is considerably more efficient than to the alpha subunit. The relative efficiency of photoactivatable cross-linking to different subunits of the receptor is a function of placement of the photoactivatable group on the toxin. Since the structures of alpha-conotoxins can be solved by 2D NMR [see Pardi et al. (1989) Biochemistry 28, 5494-5508; Kobayashi et al. (1989) Biochemistry 28, 4853-4860], this family of toxins should provide a set of new ligands for probing the acetylcholine receptor with considerable precision.

Characterization of proteinase-3 (PR-3), a neutrophil serine proteinase. Structural and functional properties

Proteinase 3 (PR-3) is a human polymorphonuclear leukocyte (PMNL) serine proteinase that degrades elastin in vitro and causes emphysema when administered by tracheal insufflation to hamsters (Kao, R. C., Wehner, N. G., Skubitz, K. M., Gray, B. H., and Hoidal, J. R. (1988) J. Clin. Invest. 82, 1963-1973). We have determined the primary structure of several PR-3 peptides and have analyzed catalytic properties of the enzyme. The enzyme has considerable amino acid sequence homology with two other well characterized PMNL neutral serine proteinases, elastase and cathepsin G. Furthermore, the NH2-terminal amino acid sequence of PR-3 is identical to that of the target antigen of the anti-neutrophil cytoplasmic autoantibodies associated with Wegener's granulomatosis. PR-3 degrades a variety of matrix proteins including fibronectin, laminin, vitronectin, and collagen type IV. It shows no or minimal activity against interstitial collagens types I and III, respectively. The analysis of peptides generated by PR-3 digestion of insulin chains and the activity profile against a panel of chromogenic synthetic peptide substrates show that PR-3 prefers small aliphatic amino acids (alanine, serine, and valine) at the P1 site. The elastase-like specificity of PR-3 is consistent with its striking sequence homology to elastase at substrate binding sites. PR-3 is inhibited by alpha 1-proteinase inhibitor (ka = 8.1 x 10(6) M-1 S-1; delay time = 25 ms) and alpha 2-macroglobulin (ka = 1.1 x 10(7) M-1 S-1; delay time = 114 ms) but not by alpha 1-anti-chymotrypsin. In contrast to elastase and cathepsin G, PR-3 is not inhibited by secretory leukoprotease inhibitor and is weakly inhibited by eglin c. Thus, PR-3 is distinct from the other PMNL proteinases.

Candida glabrata metallothioneins. Cloning and sequence of the genes and characterization of proteins

Southern blot analysis has identified several metallothionein gene sequences in a human pathogenic yeast Candida glabrata. Two of these genes encoding proteins designated MT-I and MT-II have been cloned and sequenced. No introns were found in either of the genes. The complete primary structure of MT-II was also determined by protein sequencing methods. As isolated, MT-I and MT-II consist of 62 and 51 amino acids, respectively. The only residues predicted from the nucleotide sequence but not present in the isolated protein are the amino-terminal methionines in each sequence. MT-I contains 18 cysteines, 14 of which are present as Cys-X-Cys motifs and two additional cysteines in a Cys-X-X-Cys sequence. The sequence of MT-II contains 16 cysteinyl residues, 14 of which are in Cys-X-Cys sequences. Fluorescence spectroscopy indicates the presence of Cu(I)-thiolate bonds in both proteins. The binding stoichiometries are 11-12 for MT-I and 10 for MT-II. Under certain nutritional conditions, a truncated form of MT-II was also produced. Northern analysis of the total cellular RNA from copper-treated cells showed that both MT-I and MT-II genes are regulated by this metal ion in a concentration-dependent fashion. The concentrations of MT-II mRNA appeared to be higher than that of MT-I mRNA at all concentrations of copper sulfate tested. Both genes are inducible by silver but not by cadmium salts. Cadmium ions, however, are effective in reducing the control levels of both MT-I and MT-II mRNAs.

mu-conotoxin GIIIA, a peptide ligand for muscle sodium channels: chemical synthesis, radiolabeling, and receptor characterization

The peptide conotoxin GIIIA from Conus geographus L. venom, which specifically blocks sodium channels in muscle, has been synthesized by a solid-phase method. The three disulfide bridges were formed by air oxidation. After HPLC purification, the synthetic product was shown to be identical with the native conotoxin GIIIA from Conus geographus. A high specific activity, 125I derivative of mu-conotoxin was prepared and used for binding assays to the Na channel from Electrophorus electric organ. Specific binding could be abolished by competition with tetrodotoxin. The radiolabeled toxin was specifically cross-linked to the Na channel. These studies demonstrate that mu-conotoxin GIIIA can be used to define the guanidinium toxin binding site and will be a useful ligand for understanding functionally important differences between Na channel subtypes.

Structural and functional diversity of copper-metallothioneins from the American lobster Homarus americanus

The role of copper metallothionein (CuMT) in copper metabolism and metalloenzyme activation is poorly understood. We have chosen marine crustaceans, in which a direct correlation exists between levels of Cu(I)MT and Cu(I)-hemocyanin during the molt cycle (Engel and Brouwer, Biol. Bull. 173, 239-251, 1987) as unique model systems to study the involvement of MTs in metalloprotein activation and degradation. We have isolated three low-molecular weight, cysteine-rich copper proteins from the American lobster Homarus americanus, which we designate as CuMT-1, CuMT-2, and CuMT-3, respectively. As a first attempt to fully characterize these proteins, we have determined the sequence of the first 56 amino acids of CuMT-1. The results show this protein to belong to the class I MTs, i.e., related in primary structure to equine renal MT. CuMT-1 cannot transfer its copper to copper-depleted apohemocyanin. CuMT-2 belongs to the same class of MTs as CuMT-1, but CuMT-3 does not. The latter can reactivate lobster hemocyanin containing reduced amounts of Cu(I). Spectroscopic studies show that Cu(I) transfer from CuMT-3 to apohemocyanin initially results in the formation of distorted binuclear-copper sites, which subsequently slowly return to their native stereochemical configuration. Finally, we present evidence that shows that the class I MTs in marine crustacea are involved in the sequestration of elevated levels of heavy-metal ions. These observations strongly suggest that the different forms of MT have different biological functions.

A molluscivorous Conus toxin: conserved frameworks in conotoxins

We purified and characterized a 27 amino acid toxin from a snail-hunting Conus venom, Conus textile. This toxin causes convulsive-like activity in snails and causes subordinate lobsters to assume an exaggerated dominant posture. The sequence of this peptide is Trp-Cys-Lys-Gln-Ser-Gly-Glu-Met-Cys-Asn-Leu-Leu-Asp-Gln-Asn-Cys-Cys-Asp- Gly-Tyr-Cys-Ile-Val-Leu-Val-Cys-Thr. The sequence was confirmed by determining the nucleotide sequence of a cDNA clone coding for the peptide. The conservation of Cys residues compared to the omega-conotoxins from piscivorous Conus venom suggests that toxins from different cone venoms may use only a few "Cys-motifs" as conserved structural backbones for targeting to a variety of receptors in different animals.

Metal-specific synthesis of two metallothioneins and gamma-glutamyl peptides in Candida glabrata

Cellular resistance to heavy metal cytotoxicity in most species is mediated by the binding of metal ions either to a cysteine-rich polypeptide in the metallothionein family or to short cysteine-containing gamma-glutamyl peptides. One of these metal binding systems has been found in most organisms studied. However, the yeast Candida (Torulopsis) glabrata expresses both metallothionein and the gamma-glutamyl peptides for metal detoxification, and each system is regulated in a metal-specific manner. Exposure of C. glabrata to copper salts stimulates formation of two metallothionein-like polypeptides with a cysteine content of 30 mol% and the repeated sequence Cys-Xaa-Cys. The cells synthesize gamma-glutamyl peptides upon exposure to cadmium salts. Penta- and tetrapeptides that form a cadmium-thiolate cluster in a peptide oligomer containing labile sulfur are synthesized.

Properties of a small basic Peptide from pumpkin seeds

A small basic peptide with an unusual amino acid composition has been isolated from the seeds of pumpkin, Cucurbita maxima. Amino acid analysis and sequence data show the protein to be about 36 residues in length, with an approximate composition Lys(1), Arg(14), Asp(3), (Glu + Gln)(15), Gly(1), Pro(1), Trp(1). On the basis of composition, the molecular weight is approximately 5000 daltons and the nitrogen content by weight is 20.4%. Twelve amino acids are entirely lacking. The peptide is slightly toxic to mouse B-16 melanoma cells, but its in vivo function is unknown. It does not appear to be derived from cucurbitin, the pumpkin storage globulin; however, it could be a storage peptide involved in nitrogen mobilization during the early stages of germination.

Phylogenetic specificity of cholinergic ligands: alpha-conotoxin SI

The alpha-conotoxins are small peptide neurotoxins from the venom of fish-hunting cone snails which block nicotinic acetylcholine receptors (nAChRs). We describe the purification, characterization, and chemical synthesis of a new alpha-conotoxin from Conus striatus, alpha-conotoxin SI. In contrast to other AChR ligands, alpha-SI discriminates between different vertebrate nAChRs. The sequence of alpha-conotoxin SI is Ile-Cys-Cys-Asn-Pro5-Ala-Cys-Gly-Pro-Lys10-Tyr-Ser-Cys-NH2. This sequence was confirmed by chemical synthesis. A des-Ile-alpha-SI derivative was also synthesized and is biologically active. Although alpha-conotoxin SI is highly homologous to previously described alpha-conotoxins, it has one noteworthy sequence feature which may account for its novel biological specificity. In all other alpha-conotoxins, there is a positively charged amino acid at residue 9; in alpha-conotoxin SI, this is replaced by proline. The discovery that different alpha-conotoxins can vary by orders of magnitude in their apparent affinity for different vertebrate receptors demonstrates that alpha-conotoxins will be useful probes for investigating phylogenetic differences between vertebrate nAChRs.

Total synthesis and further characterization of the gamma-carboxyglutamate-containing "sleeper" peptide from Conus geographus venom

The total synthesis of the Gla-containing "sleeper" peptide (Gly-Glu-Gla-Gla-Leu-Gln-Gla-Asn-Gln-Gla-Leu-Ile-Arg-Gla-Lys-Ser-Asn-NH2 ) from Conus geographus is described. A new strategy for the synthesis of acid-sensitive peptide amides was developed, which allowed complete deprotection and cleavage of the L-gamma-carboxyglutamate-containing peptide from the 2,4-dimethoxybenzhydrylamine resin. Synthetic sleeper peptide, after preparative high-performance liquid chromatography (HPLC) purification, was shown to be identical with the native peptide by all criteria (coelution experiments of HPLC, sequence analysis, and biological activity). In addition, a developmental switch in the behavioral symptoms induced by the peptide after intracerebral administration in mice was documented. At low doses of the peptide (4-30 pmol/g), a sleeplike state was induced in mice under 2 weeks old; in contrast, older mice became markedly hyperactive. It is proposed that, in the presence of Ca2+, the sleeper peptide assumes an alpha-helical configuration in which all the gamma-carboxyglutamate residues are located on the same side of the alpha-helix.

Invertebrate vasopressin/oxytocin homologs. Characterization of peptides from Conus geographus and Conus straitus venoms

The vasopressin-oxytocin family of peptides is of very ancient lineage, found in organisms as diverse as hydra and man. Although these peptides have been intensively studied in vertebrates, the presumably more extensive invertebrate series was defined primarily by immunological methods. In this report, we describe the purification and structures of two peptides of the vasopressin-oxytocin family from molluscs ("Conopressins"), which were found in the venom of fish-hunting marine snails of the genus Conus. The biological activity observed when the two snail peptides are injected intracerebrally into mice is very similar to that elicited by the vertebrate neurohypophyseal hormones and presumably reflects their actions upon a common receptor in the brain. The sequences of the purified peptides reveal unique features not found in the vertebrate peptide series, most notably an additional positive charge. These are the first members of the invertebrate series of the vasopressin-oxytocin family to be characterized biochemically. The sequences of these peptides are: from Conus geographus venom, Lys-conopressin-G, Cys-Phe-Ile-Arg-Asn-Cys-Pro-Lys-Gly-NH2; and from Conus striatus venom, Arg-conopressin-S, Cys-Ile-Ile-Arg-Asn-Cys-Pro-Arg-Gly-NH2.

Neuronal calcium channel antagonists. Discrimination between calcium channel subtypes using omega-conotoxin from Conus magus venom

The omega-conotoxins from the venom of fish-hunting cone snails are probably the most useful of presently available ligands for neuronal Ca channels from vertebrates. Two of these peptide toxins, omega-conotoxins MVIIA and MVIIB from the venom of Conus magus, were purified. The amino acid sequences show significant differences from omega-conotoxins from Conus geographus. Total synthesis of omega-conotoxin MVIIA was achieved, and biologically active radiolabeled toxin was produced by iodination. Although omega-conotoxins from C. geographus (GVIA) and C. magus (MVIIA) appear to compete for the same sites in mammalian brain, in amphibian brain the high-affinity binding of omega-conotoxin MVIIA has narrower specificity. In this system, it is demonstrated that a combination of two omega-conotoxins can be used for biochemically defining receptor subtypes and suggested that these correspond to subtypes of neuronal Ca2+ channels.

Neuronal calcium channel inhibitors. Synthesis of omega-conotoxin GVIA and effects on 45Ca uptake by synaptosomes

We previously described a 27-amino acid peptide neurotoxin from the venom of Conus geographus, omega-conotoxin GVIA, which inhibits neuronal voltage-activated calcium channels. In this paper we describe the total synthesis of omega-conotoxin GVIA and demonstrate that it efficiently blocks voltage-activated uptake of 45Ca by standard synaptosomal preparations from chick brain. Dihydropyridines do not block 45Ca uptake under these conditions. Thus, the omega-conotoxin-sensitive, but dihydropyridine-insensitive uptake of 45Ca2+ by chick brain synaptosomes serves as a functional assay for a Ca channel target of omega-conotoxin. The use of synthetic GVIA should rapidly accelerate our understanding of the molecular biology of Ca2+ channels and their role in neuronal function.